Literature DB >> 27354092

Quantitative T1 mapping under precisely controlled graded hyperoxia at 7T.

Alex A Bhogal1, Jeroen Cw Siero1, Jaco Zwanenburg1, Peter R Luijten1, Marielle Ep Philippens2, Hans Hoogduin1.   

Abstract

Increasing the concentration of oxygen dissolved in water is known to increase the recovery rate (R1 = 1/T1) of longitudinal magnetization (T1 relaxation). Direct T1 changes in response to precise hyperoxic gas challenges have not yet been quantified and the actual effect of increasing arterial oxygen concentration on the T1 of brain parenchyma remains unclear. The aim of this work was to use quantitative T1 mapping to measure tissue T1 changes in response to precisely targeted hyperoxic respiratory challenges ranging from baseline end-tidal oxygen (PetO2) to approximately 500 mmHg. We did not observe measureable T1 changes in either gray matter or white matter parenchymal tissue. The T1 of peripheral cerebrospinal fluid located within the sulci, however, was reduced as a function of PetO2. No significant T1 changes were observed in the ventricular cerebrospinal fluid under hyperoxia. Our results indicate that care should be taken to distinguish actual T1 changes from those which may be related to partial volume effects with cerebrospinal fluid, or regions with increased fluid content such as edema when examining hyperoxia-induced changes in T1 using methods based on T1-weighted imaging.

Entities:  

Keywords:  Brain imaging; cerebral hemodynamics; cerebrospinal fluid; magnetic resonance imaging; neurophysiology

Mesh:

Substances:

Year:  2016        PMID: 27354092      PMCID: PMC5453465          DOI: 10.1177/0271678X16656864

Source DB:  PubMed          Journal:  J Cereb Blood Flow Metab        ISSN: 0271-678X            Impact factor:   6.200


  35 in total

1.  Imaging the changes in renal T1 induced by the inhalation of pure oxygen: a feasibility study.

Authors:  Richard A Jones; Mario Ries; Chrit T W Moonen; Nicolas Grenier
Journal:  Magn Reson Med       Date:  2002-04       Impact factor: 4.668

2.  Noninvasive oxygen partial pressure measurement of human body fluids in vivo using magnetic resonance imaging.

Authors:  Greg Zaharchuk; Reed F Busse; Guy Rosenthal; Geoffery T Manley; Orit A Glenn; William P Dillon
Journal:  Acad Radiol       Date:  2006-08       Impact factor: 3.173

3.  Cerebral interstitial tissue oxygen tension, pH, HCO3, CO2.

Authors:  F T Charbel; W E Hoffman; M Misra; K Hannigan; J I Ausman
Journal:  Surg Neurol       Date:  1997-10

4.  Measurement of cerebrospinal fluid oxygen partial pressure in humans using MRI.

Authors:  Greg Zaharchuk; Alastair J Martin; Guy Rosenthal; Geoffery T Manley; William P Dillon
Journal:  Magn Reson Med       Date:  2005-07       Impact factor: 4.668

5.  Fluid-attenuated inversion recovery MR imaging: identification of protein concentration thresholds for CSF hyperintensity.

Authors:  E R Melhem; H Jara; S Eustace
Journal:  AJR Am J Roentgenol       Date:  1997-09       Impact factor: 3.959

6.  The continuous measurement of cerebrospinal fluid gas tensions in critically ill neurosurgical patients: a prospective observational study.

Authors:  B Venkatesh; R Boots; F Tomlinson; R D Jones
Journal:  Intensive Care Med       Date:  1999-06       Impact factor: 17.440

7.  Intrinsic markers of tumour hypoxia and angiogenesis in localised prostate cancer and outcome of radical treatment: a retrospective analysis of two randomised radiotherapy trials and one surgical cohort study.

Authors:  Roy Vergis; Catherine M Corbishley; Andrew R Norman; Jaclyn Bartlett; Sameer Jhavar; Michael Borre; Sara Heeboll; Alan Horwich; Robert Huddart; Vincent Khoo; Ros Eeles; Colin Cooper; Matthew Sydes; David Dearnaley; Chris Parker
Journal:  Lancet Oncol       Date:  2008-03-17       Impact factor: 41.316

8.  Brain tissue oxygen tension response to induced hyperoxia reduced in hypoperfused brain.

Authors:  Roman Hlatky; Alex B Valadka; Shankar P Gopinath; Claudia S Robertson
Journal:  J Neurosurg       Date:  2008-01       Impact factor: 5.115

9.  Cerebral oxygenation in contusioned vs. nonlesioned brain tissue: monitoring of PtiO2 with Licox and Paratrend.

Authors:  A S Sarrafzadeh; K L Kiening; T F Bardt; G H Schneider; A W Unterberg; W R Lanksch
Journal:  Acta Neurochir Suppl       Date:  1998

10.  Oxygen-Enhanced MRI Accurately Identifies, Quantifies, and Maps Tumor Hypoxia in Preclinical Cancer Models.

Authors:  James P B O'Connor; Jessica K R Boult; Yann Jamin; Muhammad Babur; Katherine G Finegan; Kaye J Williams; Ross A Little; Alan Jackson; Geoff J M Parker; Andrew R Reynolds; John C Waterton; Simon P Robinson
Journal:  Cancer Res       Date:  2015-12-09       Impact factor: 12.701
View more
  4 in total

1.  Changes in volumetric and metabolic parameters relate to differences in exposure to sub-concussive head impacts.

Authors:  Allen A Champagne; Nicole S Coverdale; Mike Germuska; Alex A Bhogal; Douglas J Cook
Journal:  J Cereb Blood Flow Metab       Date:  2019-07-15       Impact factor: 6.200

2.  Modeling the Effect of Hyperoxia on the Spin-Lattice Relaxation Rate R1 of Tissues.

Authors:  Emma Bluemke; Eleanor Stride; Daniel Peter Bulte
Journal:  Magn Reson Med       Date:  2022-06-09       Impact factor: 3.737

3.  The effects of age on resting-state BOLD signal variability is explained by cardiovascular and cerebrovascular factors.

Authors:  Kamen A Tsvetanov; Richard N A Henson; P Simon Jones; Henk Mutsaerts; Delia Fuhrmann; Lorraine K Tyler; James B Rowe
Journal:  Psychophysiology       Date:  2020-11-18       Impact factor: 4.016

4.  Whole-brain 3D FLAIR at 7T using direct signal control.

Authors:  Arian Beqiri; Hans Hoogduin; Alessandro Sbrizzi; Joseph V Hajnal; Shaihan J Malik
Journal:  Magn Reson Med       Date:  2018-02-24       Impact factor: 4.668
  4 in total

北京卡尤迪生物科技股份有限公司 © 2022-2023.